# Proving correctness of iterative algorithms

Need to prove the correctness of following algo, I see no way proving it using loop invariants, which is the only way I know to prove iterative algorithms.

Is there any other way to prove it?

``````Preconditions: n > 0, (a1,....an) is a sequence of naturals
Postconditions: S is an array of relatively prime integers (a = b or gcd(a, b) = 1)

j = 2
S = {a1}
b1 = a1
k = 1

while j <= n do:
k = 1
insert = True

while k <= length(S) do:
if gcd(bk, aj) != 1 and bk != aj:
insert = False
k = k + 1

if insert = True:
S = S + {aj}
bk = aj

j = j + 1
``````

I see that it is actually correct as a number is inserted in the array S iff it is prime relatively to all the rest items in S (according to the inner loop) but the point is to convert this idea into some formal language.

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How about an inductive proof? Prove it is correct for the first iteration, then prove that if it is true for one iteration, it is true for the next. –  Vaughn Cato Mar 23 at 17:25
@VaughnCato Thank you, I am just not sure it can be done without loop invariants, as induction is going to be used anyway –  tmac_balla Mar 23 at 17:31
@VaughnCato: this is exactly what a loop invariant is: the induction hypothesis used in the proof. –  hivert Mar 23 at 17:37
I would say induction. That is the general strategy for an iterative algorithm. –  Brian Vanover Mar 23 at 17:37
Your postcondition is always true, though. Prove that the indented while loop correctly checks whether aj is relatively prime to everything already in S, then notice that you only insert things into S that are known to be relatively prime to everything already in there. –  tmyklebu Mar 23 at 17:42